I have a rank-1 numpy.array of which I want to make a boxplot. However, I want to exclude all values equal to zero in the array. Currently, I solved this by looping the array and copy the value to a new array if not equal to zero. However, as the array consists of 86 000 000 values and I have to do this multiple times, this takes a lot of patience.

Is there a more intelligent way to do this?


This is a case where you want to use masked arrays, it keeps the shape of your array and it is automatically recognized by all numpy and matplotlib functions.

X = np.random.randn(1e3, 5)
X[np.abs(X)< .1]= 0 # some zeros
X = np.ma.masked_equal(X,0)
plt.boxplot(X) #masked values are not plotted

#other functionalities of masked arrays
X.compressed() # get normal array with masked values removed
X.mask # get a boolean array of the mask
X.mean() # it automatically discards masked values

For a NumPy array a, you can use

a[a != 0]

to extract the values not equal to zero.

  • Thank you very much, this works indeed much (!) more faster. Does similar action ca be done on higher rank NumMpy array or matrix ? Because here, the problem occurs that dimenions will no longer match properly ... – ruben baetens May 8 '11 at 12:07
  • @rubae: If a has higher dimension, the result will be a flattened (one dimensional) array. It would also be possible to remove columns or rows that are all zero. – Sven Marnach May 8 '11 at 12:51
  • ...where a is a np.array. This will not work on built-in python arrays. – noumenal Jun 18 '18 at 14:43

A simple line of code can get you an array that excludes all '0' values:



import numpy as np
array = [0, 1, 0, 3, 4, 5, 0]
array2 = np.argwhere(array)
print array2

[1, 3, 4, 5]

I would like to suggest you to simply utilize NaN for cases like this, where you'll like to ignore some values, but still want to keep the procedure statistical as meaningful as possible. So

In []: X= randn(1e3, 5)
In []: X[abs(X)< .1]= NaN
In []: isnan(X).sum(0)
Out[: array([82, 84, 71, 81, 73])
In []: boxplot(X)

enter image description here

  • ah, the use of NaN seems indeed more appropriate here, thank you. As such i no longer need to copy my data to a new array with different sizing but i can keep the original array and as such location in the array. Thank you ! – ruben baetens May 8 '11 at 17:10
  • do you perhaps know a manner to loop this using list comprehension ? i.e. i'm having a dictionary a where a[k] is a NumPy array so i wanted to do [a[k][abs(a[k])<.1]=float('NaN') for k in data] but this seems to fail in the loop, whereas only executing the command in the loop seems to work ... – ruben baetens May 8 '11 at 17:29
  • @rubae: I think you should make a separate question related to this list comprehension issue. Unfortunately it's not anymore so straightforward to figure out what you are actually aiming for :(. As far as I can guess; don't get fooled out with the list comprehension, perhaps you are only looking for something simple like this: for k in data: a[k][abs(a[k])< .1]= NaN? – eat May 8 '11 at 19:22

You can index with a Boolean array. For a NumPy array A:

res = A[A != 0]

You can use Boolean array indexing as above, bool type conversion, np.nonzero, or np.where. Here's some performance benchmarking:

# Python 3.7, NumPy 1.14.3


A = np.random.randint(0, 5, 10**8)

%timeit A[A != 0]          # 768 ms
%timeit A[A.astype(bool)]  # 781 ms
%timeit A[np.nonzero(A)]   # 1.49 s
%timeit A[np.where(A)]     # 1.58 s

I decided to compare the runtime of the different approaches mentioned here. I've used my library simple_benchmark for this.

The boolean indexing with array[array != 0] seems to be the fastest (and shortest) solution.

enter image description here

For smaller arrays the MaskedArray approach is very slow compared to the other approaches however is as fast as the boolean indexing approach. However for moderately sized arrays there is not much difference between them.

Here is the code I've used:

from simple_benchmark import BenchmarkBuilder

import numpy as np

bench = BenchmarkBuilder()

def boolean_indexing(arr):
    return arr[arr != 0]

def integer_indexing_nonzero(arr):
    return arr[np.nonzero(arr)]

def integer_indexing_where(arr):
    return arr[np.where(arr != 0)]

def masked_array(arr):
    return np.ma.masked_equal(arr, 0)

@bench.add_arguments('array size')
def argument_provider():
    for exp in range(3, 25):
        size = 2**exp
        arr = np.random.random(size)
        arr[arr < 0.1] = 0  # add some zeros
        yield size, arr

r = bench.run()

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